Distilling Fractons from Layered Subsystem-Symmetry Protected Phases

TL;DR

This paper demonstrates how 3D Type-II fracton models, specifically Haah's cubic code, can be derived from stacks of 2D subsystem-symmetry protected topological states through a process called distillation, involving long-range entanglement.

Contribution

It introduces a novel layer construction for Type-II fractons from SSPT states and develops a rigorous framework using gauge substructures for understanding distillation.

Findings

Haah's cubic code can be obtained from 2D SSPT layers.

Type-I fracton order can be distilled from SSPT states.

A protocol for realizing fracton quantum error correction codes is proposed.

Abstract

It is well-known that 3D Type-I fracton models can be obtained from the condensations of stacked layers of 2D anyons. It is less obvious if 3D Type-II fractons can be understood from a similar perspective. In this paper, we affirm that this is the case: we produce the paradigm Type-II fracton model, Haah's cubic code, from a 2D layer construction. However, this is not a condensation of 2D anyons, but rather we start with stacks of 2D subsystem-symmetry protected topological states (SSPT). As this parent model is not topologically ordered in the strict sense, whereas the final state is, we refer to this process as a distillation as we are forming a long-range entangled (LRE) state from several copies of a short-range entangled (SRE) state. We also show that Type-I fracton topological order can also be distilled from SSPT states in the form of the cluster-cube model which we introduce here. We start by introducing the Brillouin-Wigner perturbation theory of distillation. However, a more detailed analysis from which the perturbation theory follows, is also performed using linear gauge structures and an extension we introduce here referred to as gauge substructures. This allows us to rigorously define distillation as well as understand the process of obtaining LRE from SRE. We can diagnose the source of LRE as the distillation of subsystem symmetries into robust long-range ground state degeneracy as characterized by logical operators of the resulting stabilizer code. Furthermore, we find which Hamiltonian terms are necessary for selecting the ground state which results from the perturbation. This leads to a protocol for realizing a fracton quantum error correcting code initialized in a chosen fiducial state using only finite-depth circuits and local measurements.